Proof of Nuprl Lemma : real-vec-obtuse-angle

Step * 1 1 1 1 2 1 1 1 1 of Lemma real-vec-obtuse-angle

1. n : ℕ
2. x : ℝ^n
3. y : ℝ^n
4. z : ℝ^n
5. req-vec(n;r(-1)*x - y;r(2)*y - x - y)
6. d(z;r(2)*y - x) < d(z;x)
7. x' : ℝ^n
8. d(x';y) = d(x;y)
9. t : ℝ
10. t ∈ [r0, r1]
11. ∀i:ℕn. ((y i) = ((r1/r(2))*x + r1 - (r1/r(2))*x' i))
12. t = (r1/r(2))
13. i : ℕn
14. (y i) = (((r1/r(2)) * (x i)) + ((r1/r(2)) * (x' i)))
15. (r1 - (r1/r(2))) = (r1/r(2))
⊢ (x' i/r(2)) = ((y i) + -((x i/r(2))))
BY
{ ((RWO "-2" 0 THENA Auto) THEN nRNorm 0 THEN Auto) }

Latex:

Latex:
1. n : \mBbbN{} 2. x : \mBbbR{}\^{}n 3. y : \mBbbR{}\^{}n 4. z : \mBbbR{}\^{}n 5. req-vec(n;r(-1)*x - y;r(2)*y - x - y) 6. d(z;r(2)*y - x) < d(z;x) 7. x' : \mBbbR{}\^{}n 8. d(x';y) = d(x;y) 9. t : \mBbbR{} 10. t \mmember{} [r0, r1] 11. \mforall{}i:\mBbbN{}n. ((y i) = ((r1/r(2))*x + r1 - (r1/r(2))*x' i)) 12. t = (r1/r(2)) 13. i : \mBbbN{}n 14. (y i) = (((r1/r(2)) * (x i)) + ((r1/r(2)) * (x' i))) 15. (r1 - (r1/r(2))) = (r1/r(2)) \mvdash{} (x' i/r(2)) = ((y i) + -((x i/r(2)))) By Latex: ((RWO "-2" 0 THENA Auto) THEN nRNorm 0 THEN Auto) Home Index